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GB/T 36654-2018: RF technical requirements and test methods for 76 GHz vehicle radio equipment
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RF technical requirements and test methods for 76 GHz vehicle radio equipment
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GB/T 36654-2018
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Basic data | Standard ID | GB/T 36654-2018 (GB/T36654-2018) | | Description (Translated English) | RF technical requirements and test methods for 76 GHz vehicle radio equipment | | Sector / Industry | National Standard (Recommended) | | Classification of Chinese Standard | M36 | | Classification of International Standard | 33.060.20 | | Word Count Estimation | 18,146 | | Date of Issue | 2018-09-17 | | Date of Implementation | 2019-01-01 | | Issuing agency(ies) | State Administration for Market Regulation, China National Standardization Administration | GB/T 36654-2018: RF technical requirements and test methods for 76 GHz vehicle radio equipment---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.
RF technical requirements and test methods for 76 GHz vehicle radio equipment
ICS 33.060.20
M36
National Standards of People's Republic of China
76GHz vehicle radio equipment RF indicator
Technical requirements and test methods
Published on.2018-09-17
2019-01-01 implementation
State market supervision and administration
China National Standardization Administration issued
Content
Foreword III
1 Scope 1
2 Normative references 1
3 Terms and definitions, abbreviations 1
3.1 Terms and Definitions 1
3.2 Abbreviations 1
4 Technical requirements 2
4.1 Environmental requirements 2
4.2 RF Technical Requirements 2
5 Test Method 3
5.1 Environmental conditions required for testing 3
5.2 Test results and uncertainty 3
5.3 Test Configuration 4
5.4 Peak equivalent isotropic radiation power 5
5.5 Frequency range 6
5.6 Out-of-band emission 6
5.7 Occupied bandwidth 6
5.8 Transmitter spurious emissions 7
5.9 Receiver spurious emissions 8
Appendix A (Normative) Test Site for Radiation Testing 9
Appendix B (Normative) General Test Method for Radiated Spurs 11
Reference 13
Foreword
This standard was drafted in accordance with the rules given in GB/T 1.1-2009.
Please note that some of the contents of this document may involve patents. The issuing organization of this document is not responsible for identifying these patents.
This standard was proposed by the Ministry of Industry and Information Technology of the People's Republic of China.
This standard is under the jurisdiction of the National Communications Standardization Technical Committee (SAC/TC485).
This standard was drafted. National Radio Monitoring Center Testing Center.
The main drafters of this standard. Lin Lei, Feng Shaoqi, Chen Guocheng, Fu Jing, Li Meimei, Liu Xiaoyong, Wang Junfeng, Tao Hongbo, Jiang Qiuhong, Zhang Junchi,
Janda.
76GHz vehicle radio equipment RF indicator
Technical requirements and test methods
1 Scope
This standard specifies the equivalent omnidirectional radiated power, transmitter spurious emissions, and reception of vehicle radio equipment operating in the 76 GHz band.
Technical requirements and test methods for RF indicators such as spurious emissions and out-of-band emissions.
This standard applies to vehicle radio equipment operating in the frequency range of 76 GHz to 77 GHz.
2 Normative references
The following documents are indispensable for the application of this document. For dated references, only dated versions apply to this article.
Pieces. For undated references, the latest edition (including all amendments) applies to this document.
GB/T 9254-2008 Radio disturbance limits and measurement methods for information technology equipment
3 terms and definitions, abbreviations
3.1 Terms and definitions
The following terms and definitions apply to this document.
3.1.1
Equivalent isotropic radiation power equivalentisotropicradiatedpower;EIRP
The product of the power output to the antenna in the specified direction relative to the antenna gain of the omnidirectional antenna.
3.1.2
Power spectral density spectralpowerdensity
The value of the average equivalent isotropic radiated power per unit bandwidth.
3.1.3
Duty cycle dutycycle
The ratio of the duration of a positive pulse to the total period of a pulse in a series of pulse trains.
3.1.4
Spurious emission spuriousemission
Unwanted emissions of equipment in the spurious domain.
3.2 Abbreviations
The following abbreviations apply to this document.
RBW. Resolution Bandwidth (ResolutionBandwidth)
RMS. Root Mean Square (RootMeanSquare)
VBW. Video Bandwidth (VideoBandwidth)
4 Technical requirements
4.1 Environmental requirements
The equipment manufacturer shall state in advance the environmental conditions in which the equipment is to be operated, and the equipment shall operate under its nominal working environment.
4.2 RF technical requirements
4.2.1 Peak equivalent isotropic radiation power
4.2.1.1 Overview
The product of the peak power output to the antenna in the specified direction relative to the antenna gain of the omnidirectional antenna.
4.2.1.2 Limits
The transmitter operates at the maximum power level. The peak equivalent isotropic radiation power limit is 55 dBm.
4.2.2 Frequency range
When the transmitter is operating at the maximum power level. The frequency range of use is 76 GHz to 77 GHz.
4.2.3 Out-of-band emission
4.2.3.1 Overview
The out-of-band emission in this standard refers to the maximum power of the transmitter in the frequency range 73.5GHz~76GHz and 77GHz~79.5GHz.
Rate spectral density.
4.2.3.2 Limits
The out-of-band emission limit is 0dBm/MHz.
4.2.4 Transmitter spurious emissions
4.2.4.1 Overview
Transmitter spurious emissions are unwanted emissions in the spurious domain when the device is in the transmitting state.
4.2.4.2 Limits
The transmitter spurious limits are shown in Table 1.
Table 1 Transmitter spurious emission limits
Frequency Range
Emission state limit
dBm
Transmitter standby or idle state
dBm
Test bandwidth
30MHz≤f< 48.5MHz
48.5MHz≤f≤72.5MHz
72.5MHz \u003cf\u003c76MHz
76MHz≤f≤108MHz
-36
-54
-36
-54
-47
100kHz
100kHz
100kHz
100kHz
Table 1 (continued)
Frequency Range
Emission state limit
dBm
Transmitter standby or idle state
dBm
Test bandwidth
108MHz \u003cf\u003c167MHz
167MHz≤f≤223MHz
223MHz \u003cf\u003c470MHz
470MHz≤f≤566MHz
566MHz \u003cf\u003c606MHz
606MHz≤f≤798MHz
798MHz \u003cf≤1GHz
1GHz \u003cf≤40GHz
f >40GHz
-36
-54
-36
-54
-36
-54
-36
-30
-20
-47
100kHz
100kHz
100kHz
100kHz
100kHz
100kHz
100kHz
1MHz
1MHz
Note. f represents the transmitter spurious frequency.
4.2.5 Receiver spurious emissions
4.2.5.1 Overview
Receiver spurious emissions are unwanted emissions in the spurious domain when the device is in the receiving state.
4.2.5.2 Limits
Receiver spurious limits are shown in Table 2.
Table 2 Receiver spurious emission limits
Frequency Range
Limit
dBm
Test bandwidth
30MHz≤f≤1GHz -57 100kHz
f >1GHz -47 1MHz
Note. f represents the transmitter spurious frequency.
5 test methods
5.1 Environmental conditions required for testing
The device under test should work in its normal working environment.
a) Temperature. 15 ° C ~ 35 ° C;
b) Relative humidity. 20%~75%.
5.2 Test results and uncertainty
The complete test result expression should consist of the following parts.
a) measured values and corresponding limits;
b) Measurement uncertainty.
The measurement uncertainty should not be greater than the values in Table 3.
Table 3 Measurement uncertainty
Project uncertainty
Frequency ±1×10-7
Power (below 100 GHz) ±6 dB
Humidity ±5%
Temperature ± 1 ° C
5.3 Test Configuration
5.3.1 Test fixture
Equipment manufacturers are required to provide appropriate fixtures to allow the equipment to be placed in a stable position and to ensure that the equipment antenna is in the same water as the test receiver antenna
Flat line. As shown in Figure 1.
The test fixture requirements are as follows.
a) The matching load of the joints and waveguides used in the test shall be 50Ω;
b) The joints and waveguides used in the test shall be matched to the load standing wave ratio of not more than 1.5;
c) The receiving antenna gain should be no less than 20dB.
Figure 1 Schematic diagram of the test fixture
5.3.2 Test site
The test site shall be a fully shielded room with RF absorbing material in the room to simulate the free space environment in which electromagnetic waves propagate. It is
Complete the replacement site for the device's radiation emission test. The test arrangement of the measuring antenna, the device under test and its alternative antenna is the same as the open test field
Like, but their erection height from the floor is fixed. as shown in picture 2.
The test site requirements are as follows.
a) The shielding efficiency of the anechoic chamber used in the test shall be greater than 105 dB;
b) The anechoic chamber return loss used in the test shall be greater than 30 dB;
c) The equipment used in the test, the measuring antenna and the replacement antenna should be calibrated regularly.
Figure 2 Test site
5.3.3 Test Block Diagram
For the equipment specified in this standard, the test block diagram shown in Figure 3 should be used for testing. The test attachment requirements are as follows.
a) The matching load of the mixer, signal generator, waveguide flange, etc. used in the test shall be 50Ω;
b) The VSWR of the mixer, signal generator, waveguide flange, etc. used in the test shall be less than 1.5;
c) The mixer, signal generator, waveguide flange, etc. used in the test should be calibrated periodically.
Figure 3 test block diagram
5.4 Peak equivalent isotropic radiation power
5.4.1 Test Block Diagram
The peak equivalent isotropic radiated power shall be measured using the test site described in 5.3.2 and the method in 5.3.3.
5.4.2 Measurement steps
The measurement steps are as follows.
a) Connect the device under test to a matching diode detector or equivalent via a suitable attenuator. Diode detection
The output of the unit should be connected to the vertical channel of an oscilloscope or equivalent power measuring device. Diode detector and oscilloscope
The combination should be able to accurately reproduce the duty cycle of the transmitter output signal;
b) Use the spectrum analyzer to measure the output power of the transmitter, using the RMS detection method. At this time, the device under test should use the highest power.
Level launch. The observed value is recorded as A;
c) The peak equivalent isotropic radiated power Ppeak shall be calculated from the measured power output A and the observed duty cycle x, detailed
The calculation method is shown in equation (1).
Ppeak=A 10×lg(1/x) (1)
In the formula.
Ppeak---peak equivalent isotropic radiation power in decibel milliwatts (dBm);
A --- measured output power in decibel milliwatts (dBm);
x --- Transmitter output signal duty cycle.
5.5 Frequency range
5.5.1 Test Block Diagram
The frequency range shall be measured using the test site described in 5.3.2 and the method in 5.3.3.
5.5.2 Measurement steps
The measurement steps are as follows.
a) the transmitter is adjusted to the maximum transmission mode;
b) Use the spectrum analyzer to read the start frequency and cutoff frequency of the signal envelope and record it, the value of which shall not exceed the 4.2.2 mid-limit requirement.
5.6 Out-of-band emission
5.6.1 Test Block Diagram
Out-of-band emissions shall be measured using the test site described in 5.3.2 and the method in 5.3.3.
5.6.2 Measurement steps
The measurement steps are as follows.
a) the transmitter is adjusted to the maximum transmission mode;
b) Set the spectrum analyzer start frequency = 73.5GHz, cutoff frequency = 76GHz, RBW = 1MHz, VBW = 1MHz, detector
Mode RMS, the maximum tracking mode is maintained;
c) record the maximum value of the out-of-band emission, the value of which shall not exceed the limit of 4.2.3;
d) Set the spectrum analyzer start frequency = 77GHz, cutoff frequency = 79.5GHz, RBW = 1MHz, VBW = 1MHz, detector
Mode RMS, the maximum tracking mode is maintained;
e) Record the maximum value of the out-of-band emissions, the value of which shall not exceed the mid-limit of 4.2.3.
5.7 Occupied bandwidth
5.7.1 Test Block Diagram
The occupied bandwidth shall be measured using the test site described in 5.3.2 and the method in 5.3.3.
5.7.2 Measurement steps
The measurement steps are as follows.
a) the transmitter is adjusted to the maximum transmission mode;
b) Set the spectrum analyzer center frequency = the center frequency of the channel under test, RBW = 1MHz, VBW = 1MHz, sweep width
2 times the nominal channel bandwidth, the detector mode RMS, the tracking mode maximum is maintained;
c) Record the bandwidth of the 99% of the signal displayed on the spectrum analyzer.
5.8 Transmitter spurious emissions
5.8.1 Configuration Requirements
If the transmitter uses an antenna array that distributes power symmetrically, only one transmit link (antenna) should be reserved, where practicable,
Disable other transmit links (antennas) and, if not feasible, document the method used in the test report.
If only one transmit link is tested, the test results should be corrected to apply to the entire system (all transmit links). One
The transmit power (mW) of the transmit link needs to be multiplied by the number of transmit links to obtain the total transmit power of the system.
The device under test should be configured to operate at the maximum duty cycle and maximum output power level.
5.8.2 Stray emission test method not greater than 40 GHz
5.8.2.1 Test Block Diagram
When detecting spurious emissions less than or equal to 40 GHz, use the test site described in Appendix A and the relevant measurement procedures in Appendix B.
Make measurements.
5.8.2.2 Measurement steps
The measurement steps are as follows.
a) Measure spurious emissions in the range of 30MHz~1GHz, set the spectrum analyzer RBW=100kHz, VBW=100kHz check
Wave filter RMS, tracking mode maximum value is maintained;
b) measuring spurious emissions in the range of 1 GHz to 40 GHz, setting the spectrum analyzer RBW = 1 MHz, VBW = 1 MHz detector
RMS, the tracking mode maximum is maintained;
c) Any emissions found in the scan that are within 6 dB below the limit shall be recorded. If the measurement is outside the specified distance
To carry out, the calculation result of the equivalent field strength value should be given.
5.8.3 Spurious emission test method greater than 40 GHz
5.8.3.1 Test block diagram
When detecting spurious emissions greater than 40 GHz, measurements shall be made using the test sites described in 5.3.2 and the methods in 5.3.3.
5.8.3.2 Measurement steps
The measurement steps are as follows.
a) Test the spurs of the highest frequency band and record when the device supports, set the spectrum analyzer RBW=1MHz, VBW=
1MHz, detector RMS, tracking mode maximum hold;
b) Any emissions found in the scan that are within 6 dB below the limit shall be recorded. Analyze the mixer for the results
The impact of mirroring.
5.9 Receiver spurious emissions
5.9.1 Configuration Requirements
If the receiver is in the form of an antenna array, only one transmit link (antenna) should be reserved, and other emissions should be disabled, where practicable.
Link (antenna), if not feasible, the method used should be documented in the test report.
If only one receive link is tested, the test results should be corrected to apply to the entire system (all receive links).
The spurious transmit power (mW) of a receive link needs to be multiplied by the number of receive links to obtain the total receiver spurious emissions of the system.
Shooting power.
The device under test should be configured to operate in a state of continuous reception or no transmission.
5.9.2 Stray emission test method not greater than 40 GHz
5.9.2.1 Test Block Diagram
Use the test site described in Appendix A and the relevant measurement procedures in Appendix B when detecting spurious emissions less than or equal to 40 GHz.
Make measurements.
5.9.2.2 Measurement steps
The measurement steps are as follows.
a) Measure spurious emissions in the range of 30MHz~1GHz, set the spectrum analyzer RBW=100kHz, VBW=100kHz check
Wave filter RMS, tracking mode maximum value is maintained;
b) measuring spurious emissions in the range of 1 GHz to 40 GHz, setting the spectrum analyzer RBW = 1 MHz, VBW = 1 MHz detector
RMS, the tracking mode maximum is maintained;
c) Any emissions found in the scan that are within 6 dB below the limit shall be recorded. If the measurement is outside the specified distance
To carry out, the calculation result of the equivalent field strength value should be given.
5.9.3 Spurious emission test method greater than 40 GHz
5.9.3.1 Test block diagram
When detecting spurious emissions greater than 40 GHz, measurements shall be made using the test sites described in 5.3.2 and the methods in 5.3.3.
5.9.3.2 Measurement steps
The measurement steps are as follows.
a) Test the spurs of the highest frequency band and record when the device supports, set the spectrum analyzer RBW=1MHz, VBW=
1MHz, detector RMS, tracking mode maximum hold;
b) Any emissions found in the scan that are within 6 dB below the limit shall be recorded. Analyze the mixer for the results
The impact of mirroring.
Appendix A
(normative appendix)
Test site for radiation testing
A.1 open test field or semi-anechoic darkroom
Open test or semi-anechoic darkrooms shall comply with the requirements of the test site in Appendix A of GB/T 9254-2008.
In the frequency band below 1 GHz, the test distance of the transmitting and receiving antennas is not less than 3 m. Select the appropriate test in the frequency band above 1 GHz
distance. The size of the device under test should be less than 20% of the test distance. The height of the equipment to be tested or the height of the replacement antenna frame is 1.5m, the measurement day
The height of the wire frame is adjusted within the range of 1m~4m.
In order to ensure that the reflected wave signal generated by obstacles near the test site has no effect on the test results, the test site should meet the following requirements.
condition.
a) There shall be no conductive objects in the vicinity of the test site that are larger than the test maximum frequency λ/4 (λ is the wavelength of the electric wave);
b) Connect the cables as far as possible along the floor surface, preferably under the floor, and shielded cables for low-impedance cables.
A typical test site layout is shown in Figure A.1.
Figure A.1 Test site layout
A.2 Full anechoic chamber
A.2.1 Overview
The full anechoic chamber is a fully shielded room with RF absorbing material inside, which is used to simulate the free space environment of electromagnetic wave propagation. It is
Complete the replacement site for the device's radiation emission test. The test arrangement of the measuring antenna, the device under test and its alternative antenna is the same as the open test field
Like, but their erection height from the floor is fixed.
See Table A.1, Table A.2 for the requirements for the shielding effectiveness and wall reflection loss of the full anechoic chamber. Requires full-wave darkroom to be tested
The deviation of the space transmission loss from the device to the measuring antenna to the transmission loss in the free space environment is within ±4 dB.
Table A.1 Requirements for shielding effectiveness of full anechoic chambers
Frequency Range
Shielding effectiveness minimum limit
dB
10kHz~100kHz 60
100kHz~30MHz 80
30MHz~40GHz 105
Table A.2 Requirements for wall reflection loss of all-wave darkroom
Frequency Range
Minimum reflection loss limit
dB
30MHz~100MHz 10
100MHz~300MHz 22
300MHz~40GHz 30
A.2.2 Test antenna
The physical size of the measuring antenna cannot exceed 20% of the test distance. The measuring antenna should be suitable for the reception of polarized waves and should be installed at the level
The end of the arm should allow the antenna to be positioned and mounted according to the horizontal or vertical component of the measured electric field. When oriented vertically and at the lowest
When installing the position, the low end of the antenna should be at least 0.3m from the ground.
A.2.3 Alternative antenna
The gain accuracy of the alternative antenna is within ±1 dB.
Appendix B
(normative appendix)
General test method for radiated spurs
B.1 Radiation spurious test
The radiated spur test shall be carried out in the full anechoic chamber in accordance with the arrangement of Figure B.1. When testing, the measuring antenna is facing the most of the device under test.
The large radiation level orientation is recorded in the test report and measured in that direction.
Figure B.1 Schematic diagram of test layout
The radiation spur test steps are as follows.
a) The test site shall meet the test requirements of the specified test frequency band, and the device under test shall be placed on the standard turntable (or bracket) unless otherwise required
Therefore, the measuring antenna should be vertically polarized to the device under test, and the height of the antenna is the same as the height of the device under test.
b) Set the spectrum analyzer to peak detection. Scanning within the specified radiated spurious test frequency band, searching for the exemption band
A valid spurious spectral component produced by the device under test. If necessary, raise and lower the measuring antenna in a small range,
Allows the spectrum analyzer to obtain the maximum power reading of the effective output spectral components.
c) Rotate the device under test to get the maximum level reading of the spectrum analyzer. If necessary, again, the measuring antenna is in a smaller range.
Line up and down, allowing the spectrum analyzer to obtain a larger level reading based on the above maximum level reading, recording the frequency of the effective spectral components
The rate and maximum level readings are in the test report.
d) Set the measurement antenna to the horizontal polarization position and repeat the above test procedure.
B.2 Alternative measurement
The test data obtained by the test method of B.1 is not the final test result, and the actual transmit power of the spurious signal generated by the device under test.
Ping needs to be determined by an alternative test. The principle of the alternative test is to replace the device under test with a known signal generator to give a quantitative measurement.
The emission level of each signal generated by the device, the test connection is shown in Figure B.2. Instead of using an antenna to replace the device under test in the original position,
And it is a vertical polarization mode, and the signal generator frequency is tuned to the test frequency of each signal in the B.1 test process. Adjustment signal generation
The output power is such that the measurement spectrum analyzer achieves the same test level as recorded during the B.1 test. Corresponding frequency letter
The radiation emission power of the number is the sum of the signal generator output level and the gain of the replacement antenna minus the calculated value after the connection cable loss.
This gives the actual radiated power of each frequency signal.
Figure B.2 Schematic diagram of the alternative test layout
references
[1] Technical requirements for micropower (short range) radio equipment (No. [2005] No. 423)
[2] ETSIEN301091-1V1.3.3 ElectromagneticcompatibilityandRadiospectrum Matters
(ERM); ShortRangeDevices; RoadTransport andTrafficTelematics (RTTT); Radarequipmentop-
Eratinginthe76GHzto77GHzrange;Part 1.Technicalcharacteristicsandtestmethodsforradare-
Quimmentoperatinginthe76GHzto77GHzrange
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